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1 of 33 © Boardworks Ltd 2008 Transport across the cell membrane All cells are surrounded by a partially-permeable membrane that controls what substances can enter and exit the cell. A cell needs to be able to import the substances it needs to survive, and to export waste materials and substances that are needed outside the cell. There are several methods by which substances (molecules and ions) can cross the cell membrane: diffusion osmosis active transport. What is diffusion? Diffusion is the net movement of particles down a concentration gradient: from a region of high concentration to a region of low concentration. net movement of particles No metabolic energy is expended during diffusion so it is an example of passive transport. One example of diffusion is gas exchange across respiratory surfaces, such as the lungs of mammals and birds, and the gills of fish. The rate of diffusion The rate of diffusion in a given direction across an exchange surface can be summarized by Fick’s law, which states that: rate of diffusion is proportional to: surface area × difference in conc. length of diffusion path (membrane thickness) Increasing the surface area across which the particles diffuse, or increasing the size of the concentration gradient will increase the rate of diffusion. Increasing the distance (or thickness of the membrane) over which diffusion takes place will decrease the rate. What factors affect diffusion? Cell membranes, polarity and diffusion The non-polar, hydrophobic tails of phospholipid molecules in a cell membrane act as a barrier to most substances. Generally, the smaller and less polar a molecule, the easier and faster it will diffuse across a cell membrane. Small, non-polar molecules such as oxygen and carbon dioxide rapidly diffuse across a membrane. Small, polar molecules, such as water and urea, also diffuse across, but much more slowly. Charged particles (ions) cannot diffuse across a membrane, even if they are very small. Facilitated diffusion Diffusion What is osmosis? Osmosis is the diffusion of water. It is the net movement of water molecules from a region of high water concentration to a region of low water concentration, through a partiallypermeable membrane. net movement of water molecules Osmosis is the process by which cells exchange water with their environment, such as in the mammalian kidney. What is water potential? The net movement of water by osmosis is determined by differences in water potential between two solutions connected by a partially-permeable membrane. Water potential is the tendency of water molecules in a system to move. It is denoted by the symbol Ψ and is measured in kiloPascals (kPa). Pure water has the highest water potential, and has a value of 0 kPa. Solutions have a lower water potential than pure water, and have a negative water potential. Water molecules always move from a region of high water potential to a region of low (more negative) water potential. Water movement during osmosis What is solute potential? The water potential of a solution is affected by the amount of solute it contains. The greater the amount of solute, the lower the water potential. This is because water molecules bind to the solute molecules, reducing the number of water molecules that are free to diffuse. free water molecule solute molecule The contribution that solutes make to the water potential of a solution is the solute potential (ΨS), and is a negative value. What is pressure potential? The water potential of a solution is also affected by the pressure applied to it. The greater the pressure, the higher the water potential. This is called the pressure potential (ΨP) and is always a positive value. In plant cells, the pressure potential is a result of the cell wall exerting pressure on the cytoplasm. Water potential is calculated using the following equation: water potential Ψ = = solute potential ΨS + + pressure potential ΨP Calculating water potential Osmosis in plant cells Osmosis in animal cells Water potential of potatoes Osmosis: true or false? Direction of water movement What is active transport? Diffusion is very important for helping to maintain the internal environment of a cell. However, molecules and ions often need to be moved across a membrane against their concentration gradient. The cell uses carrier proteins to pump these substances across the membrane, in a process called active transport. This process requires the expenditure of energy in the form of ATP (adenosine triphosphate), a molecule produced by respiration in mitochondria. Examples of active transport Active transport is used in many processes, such as the: uptake of glucose and amino acids in the small intestine absorption of mineral ions by plant roots excretion of hydrogen ions and urea by kidneys exchange of sodium and potassium ions in neurons and muscle cells. Cells that undertake active transport on a large scale have many mitochondria. Active transport What is bulk transport? When extremely large substances need to be moved across a cell membrane, bulk transport is used. The two types of bulk transport are endocytosis and exocytosis, and they involve changes to the membrane shape. Endocytosis is the bulk transport of material in to the cell, and can be split into three processes: phagocytosis, pinocytosis and receptor-mediated endocytosis. Exocytosis is the bulk transport of material out of the cell – essentially the reverse of endocytosis. Mechanisms of endocytosis Exocytosis